Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS

Y04—INFORMATION OR COMMUNICATION TECHNOLOGIES HAVING AN IMPACT ON OTHER TECHNOLOGY AREAS

Y04S40/00—Systems for electrical power generation, transmission, distribution or end-user application management characterised by the use of communication or information technologies, or communication or information technology specific aspects supporting them

Y04S40/10—Systems for electrical power generation, transmission, distribution or end-user application management characterised by the use of communication or information technologies, or communication or information technology specific aspects supporting them characterised by communication technology

Y04S40/16—Details of management of the overlaying communication network between the monitoring, controlling or managing units and monitored, controlled or operated electrical equipment

Y04S40/164—Details of management of the overlaying communication network between the monitoring, controlling or managing units and monitored, controlled or operated electrical equipment related to network topology

Abstract

A CCN-deployment system can design and deploy a content centric network (CCN) topology, either across a collection of CCN nodes or across an existing computer network. During operation, the system analyzes a computer network of N network nodes to determine a physical network topology. The system also determines a number, k, of network nodes of the physical network on which to overlay a content centric network (CCN). The system then determines an average degree of connectivity, and a degree-of-connectivity distribution, that achieves an optimal performance metric for the CCN overlay network. The system generates a network topology of k network nodes that satisfies the average degree of connectivity, and that satisfies the degree-of-connectivity distribution. The system can deploy the content centric network topology across k nodes of the underlying physical network.

Description

BACKGROUND

Field

This disclosure is generally related to computer networks. More specifically, this disclosure is related to deploying an overlay content centric network across an Internet Protocol network.

Related Art

Recent research efforts are producing content centric networking (CCN) to re-architect the entire network stack around content. In CCN, packets typically do not contain network addresses for a source and a destination of the packet. Rather, clients issue requests for Content Objects, and routers across the network route these requests directly through the network to a closest network node that stores a copy of the content, which returns a packet that includes the requested Content Object to respond to the request.

CCN can use controlled flooding as a mechanism to route the requests to the appropriate content providers, which eliminates the burden of having to configure explicit routes to all possible content providers. However, the benefits produced by this mechanism comes at the cost of an increased overhead of the object-requesting traffic in the network. To make matters worse, the way CCN nodes are connected to each other has a major impact in the amount of Interests present in the network, which makes it difficult to deploy a CCN network without a debilitating overhead. For example, a sub-optimal CCN topology may cause Interests to flow via an undesirably large number of links, and can produce network congestion at certain CCN nodes. This sub-optimal topology can result in unnecessary processing overhead at the CCN nodes, and can increase the delivery time for content accessed by these Interests.

SUMMARY

One embodiment provides a system that designs and deploys a content centric network (CCN) topology, either across a collection of CCN nodes or across an existing Internet Protocol (IP) network as an overlay. During operation, the system analyzes a computer network of N network nodes to determine a physical network topology. The system also determines a number, k, of network nodes of the physical network on which to overlay a content centric network (CCN). The system then determines topology specific properties such as average degree of connectivity, and a degree-of-connectivity distribution, that achieves an optimal performance metric for the CCN overlay network. The system generates a network topology of k network nodes that satisfies the average degree of connectivity, and that satisfies the degree-of-connectivity distribution (or any other alternative or additional requirement). The system can deploy the content centric network topology across k nodes of the underlying physical network.

In some embodiments, the overlay CCN network can forward Interest messages based on a name for a piece of data, using the IP-based physical network. In CCN, each piece of content is individually named, and each piece of data is bound to a unique name that distinguishes the data from any other piece of data, such as other versions of the same data or data from other sources. This unique name allows a network device to request the data by disseminating a request or an Interest that indicates the unique name, and can obtain the data independent from the data's storage location, network location, application, and means of transportation. The following terms describe elements of a CCN architecture:

Content Object: A single piece of named data, which is bound to a unique name. Content Objects are “persistent,” which means that the unique name and data are bound via a cryptographic signature. A Content Object can move around within a computing device, or across different computing devices, but does not change. If any component of the Content Object changes, the entity that made the change creates a new Content Object that includes the updated content, and binds the new Content Object to a new unique name via a new cryptographic signature.

Unique Names: A name in a CCN is typically location independent and uniquely identifies a Content Object. A data-forwarding device can use the name or name prefix to forward a packet toward a network node that generates or stores the Content Object, without requiring a network address or physical location for the Content Object. In some embodiments, the name may be a hierarchically structured variable-length identifier (HSVLI). The HSVLI can be divided into several hierarchical components, which can be structured in various ways. For example, the individual name components parc, home, ndn, and test.txt can be structured in a left-oriented prefix-major fashion to form the name “/parc/home/ndn/test.txt.” Thus, the name “/parc/home/ndn” can be a “parent” or “prefix” of “/parc/home/ndn/test.txt.” Additional components can be used to distinguish between different versions of the content item, such as a collaborative document.

In some embodiments, the name can include a non-hierarchical identifier, such as a hash value that is derived from the Content Object's data (e.g., a checksum value) and/or from elements of the Content Object's name. A description of a hash-based name is described in U.S. patent application Ser. No. 13/847,814 (entitled “ORDERED-ELEMENT NAMING FOR NAME-BASED PACKET FORWARDING,” by inventor Ignacio Solis, filed 20 Mar. 2013), which is hereby incorporated by reference. A name can also be a flat label. Hereinafter, “name” is used to refer to any name for a piece of data in a name-data network, such as a hierarchical name or name prefix, a flat name, a fixed-length name, an arbitrary-length name, or a label (e.g., a Multiprotocol Label Switching (MPLS) label).

Interest: A packet that indicates a request for a piece of data, and includes a name (or a name prefix) for the piece of data. A data consumer can disseminate a request or Interest across an Content-Centric Network, which CCN routers can propagate toward a storage device (e.g., a cache server) or a data producer that can provide the requested data to satisfy the request or Interest.

In some embodiments, the methods disclosed herein are also applicable to other information centric networking (ICN) architectures, such as a named data network (NDN). A description of a CCN architecture is described in U.S. patent application Ser. No. 12/338,175 (entitled “CONTROLLING THE SPREAD OF INTERESTS AND CONTENT IN A CONTENT CENTRIC NETWORK,” by inventors Van L. Jacobson and Diana K. Smetters, filed 18 Dec. 2008), which is hereby incorporated by reference.

In some embodiments, the performance metrics include at least one of: Interest overhead; a number of Interest retransmissions; available network bandwidth; a network utilization; and an Interest-to-Content-Object round-trip delay.

In some embodiments, while determining the average degree of connectivity, the system iterates over one or more values for average degrees of connectivity to generate a network topology of k network nodes for each average degree of connectivity. The system computes a performance metric for each network topology, and selects an average degree of connectivity with a highest performance metric.

In some embodiments, while determining the degree-of-connectivity distribution, the system determines an optimal distribution based on a power-law distribution, based on a Gaussian distribution, or parameters associated with the distribution. The system can also determine an optimal distribution based on any other probability distribution now known or later developed, and/or with parameters associated with the distribution.

In some embodiments, while determining the degree-of-connectivity distribution, the system iterates over one or more distribution functions to generate a network topology of k network nodes that satisfies the average degree of connectivity based on a corresponding distribution function. The system then computes a performance metric for each network topology, and selects a degree-of-connectivity distribution with a highest performance metric.

In some embodiments, while determining the degree-of-connectivity distribution, the system iterates over one or more parameters for the distribution function to generate a network topology of k network nodes that satisfies the average degree of connectivity based on each distribution function. The system then computes a performance metric for each network topology, and selects network parameters with a highest performance metric.

In some embodiments, while determining the degree-of-connectivity distribution, the system determines an optimal degree-distribution matrix that specifies an occurrence value for each pair of degrees of connectivity. The degree-distribution matrix achieves an optimal performance metric for a network topology of k network nodes that satisfies the average degree of connectivity.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 illustrates an exemplary content centric network overlaid across an IP network in accordance with an embodiment.

FIG. 2 presents a flow chart illustrating a method for deploying an overlay content centric network across an IP network in accordance with an embodiment.

FIG. 3A illustrates an exemplary degree-of-connectivity distribution in accordance with an embodiment.

FIG. 3B illustrates an exemplary degree-distribution matrix in accordance with an embodiment.

FIG. 4 presents a flow chart illustrating a method for determining an average degree of connectivity that optimizes a performance metric in accordance with an embodiment.

FIG. 5 presents a flow chart illustrating a method for determining a distribution function and function parameters that optimize a performance metric in accordance with an embodiment.

FIG. 6 illustrates an exemplary apparatus that facilitates deploying an overlay content centric network across an IP network in accordance with an embodiment.

FIG. 7 illustrates an exemplary computer system that facilitates deploying an overlay content centric network across an IP network in accordance with an embodiment.

In the figures, like reference numerals refer to the same figure elements.

DETAILED DESCRIPTION

The following description is presented to enable any person skilled in the art to make and use the embodiments, and is provided in the context of a particular application and its requirements. Various modifications to the disclosed embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the present disclosure. Thus, the present invention is not limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein.

OVERVIEW

Embodiments of the present invention provide a CCN-deployment system that solves the problem of determining an optimal network topology for a content centric network (CCN), such as when deploying the CCN network on a network where every node has CCN capabilities, or when deploying a CCN overlay on top of the Internet or any physical network. For example, a physical network can include a set of routers, servers, and client devices, each of which is tied to an IP address. Specifically, each IP address corresponds to a specific network node of the physical IP network, and nodes in the physical network can forward a data packet to an intended recipient based on its IP address. However, in a CCN network, an Interest message specifies a name for a piece of data being requested, and nodes across the CCN network can forward the Interest message to reach any device that can provide the data.

In some embodiments, the CCN-deployment system can determine a network topology for the CCN network, and deploys the CCN network across the physical IP network as an overlay network, using a subset of the nodes in the IP network. While deploying the CCN network, the CCN-deployment system may create the appropriate faces (e.g., physical or virtual interfaces) or virtual links across the physical IP network that implement the CCN topology. Also, the CCN network's topology can influence the performance of the overlay CCN network. Hence, the system can test various topology parameters using one or more performance metrics to determine which topologies achieve near-optimal performance metrics. The connectivity properties of the CCN topology can have a major impact in the amount of Interests present in the network. For instance, a sub-optimal CCN topology may cause Interests to flow via an undesirably large number of links, and can produce network congestion at certain CCN nodes.

The system can use graph characterization as well as connectivity information among the CCN nodes to create the overlay CCN network, and to predict performance metrics for the overlay network. These performance metrics can include typical network performance metrics, as well as CCN-specific performance metrics such as a number (or percentage) of CCN Interests messages that are transmitted or retransmitted, an overhead due to these Interests messages, an expected time to retrieve the Content Object, etc.

The system can use these predicted metrics as well as measurements gathered from the live network to fine-tune the overlay network's topology, such as by creating new CCN faces (or links) or tearing down existing CCN faces to achieve an optimal CCN network topology. For example, if a network provider wants to deploy CCN on k nodes of a physical network, the system can compute the best CCN overlay topology design (e.g., a mesh topology, a tree topology etc.) based on the connectivity properties of each overlay network to predict the performance metrics. The operator or the CCN-deployment system can adjust the overlay CCN network by dynamically adding or removing CCN edges based on the CCN topology produced by the system.

FIG. 1 illustrates an exemplary content centric network 102 overlaid across a physical network 100 in accordance with an embodiment. Computing environment 100 can include a physical network 102, which can include any wired or wireless network that interfaces various computing devices to each other, such as a computer network implemented via one or more technologies (e.g., Bluetooth, Wi-Fi, cellular, Ethernet, fiber-optic, etc.).

In some embodiments, physical network 100 may include a pre-existing computer network, such as an IP-based network. The CCN-deployment system can select a subset of physical network 100 to use for deploying an overlay CCN network 116 (illustrated using bold lines in physical network 102). For example, the system can determine that a four-node overlay CCN network can have a near-optimal performance when the overlay CCN network has a certain topology (e.g., a tree topology, or a topology with a certain average degree or a certain degree distribution). Hence, the system can deploy overlay CCN network 116 by configuring edge node 106 and edge node 108 to also function as CCN nodes. Edge nodes 106 and 108 can include a forwarding information base (FIB) for processing and forwarding Interests, a pending interest table (PIT) for processing and forwarding Content Objects, and a Content Store (CS) for caching Content Objects. The system can also configure router nodes 104 and 106 to operate as CCN nodes due to their high degree of connectivity. Specifically, the system can configure router node 104 to operate as a hub of overlay CCN network 116 due to its connectivity to the other nodes of CCN network 116.

In some embodiments, the system can maintain overlay CCN network 116 to ensure that it maintains a desired topology. For example, if a link or a CCN face fails, or if a CCN node goes offline or becomes unreachable (e.g., router node 104 or 110), the system can select other nodes in the physical network to use to preserve the same topology, or can deploy an alternative CCN network topology that achieves near-optimal performance metrics.

Designing a CCN Topology

The CCN-deployment system characterizes network topology properties that contribute to the increase in the Interests overhead, and that impact the time to deliver content, and use this property characterization information to design optimal CCN overlays. For example, the system can first isolate the topological properties that impact CCN Interest overhead and the time to deliver content. To achieve this, the system analyzes graph properties in a dK-series of graphs to determine how they are interconnected. These graphs include n nodes, where degrees k1, k2, . . . kp are the unique degrees in the graph. The number of unique degrees p does not need to be equal to the size of the graph n, as multiple nodes may have the same degree.

The system can generate a set of dK-graphs that reproduce a correlation between each dK property and the degrees of connectivity in all d-sized sub-graphs of an underlying graph (e.g., an underlying N-node physical network topology). When d=0, 0K-graphs reproduce the average degree of connectivity of the underlying graph. For d=1, 1K-graphs reproduce the degree-of-connectivity distribution of the underlying graph. When d=2, 2K-graphs reproduce the joint degree distribution of the given graph. Extending this series in a similar fashion, when d=n, the generated nK-graphs are isomorphic to the underlying graph. In summary, each property in the dK-series embeds increasingly more information about the underlying graph's structure, and thus the corresponding dK-graphs are increasingly constrained, until the dK-graphs converge to the underlying graph.

The system can generate the dK-graphs by generating random graph structures that satisfy the dK-distribution, and measures the expected CCN performance metrics (e.g., the Interest overhead and time to deliver content) for each chosen distribution. These dK-graphs can reveal the distribution of topological properties for various graph topologies, such as the average node degree or the probability of finding k+1 nodes interconnected in a given structure (e.g., a tree structure, a mesh structure, etc.). For example, 2K-graphs can reveal the probability that a node of degree m connects to another node with degree p. Further, 3K-graphs can capture the probability distribution of loops up to 3 nodes. Once the dK distribution is revealed, the dK-graph constructing algorithm can be used to construct random graphs that represent this distribution.

In some embodiments, the system can characterize 2K-graphs by their assortativity coefficient, which summarizes the 2K-graph configuration distribution in one single value. The system can map performance metric values (e.g., an expected CCN traffic overhead and a time to deliver content) to the corresponding assortativity coefficient that describes the topological properties of a specific 2K family of graphs.

The system can also generate a plot graph that illustrates this mapping, with the performance metrics on the x-axis and the assortativity coefficients on the y-axis, to allow network administrators to easily choose an assortativity coefficient that best suits the needs of their CCN infrastructure. The plot graph can include a plot for each different performance metric being used to analyze the dK-graphs, which illustrates the correlation between the assortativity coefficients (and the various corresponding graph structures) to the various different performance metrics.

In some embodiments, the system can automatically (e.g., without human intervention) compute a near-optimal assortativity coefficient value by searching for and identifying an assortativity coefficient that optimizes one or more predetermined performance metrics (e.g., by minimizing both the average path length and the average Interests count).

The system can also analyze higher-order dK-graphs. For example, the system can analyze 3K-graph probability distributions to compute a clustering coefficient. These 3K graphs can yield more information about the graph topological constraints, but doing so requires a significantly higher computational overhead. As a work around to this problem, the system can generate smaller 3K-graphs to analyze their graph topological constraints, and compare their clustering coefficients. Then, after selecting a graph structure that satisfies the topological constraints, the system can use a graph scaling algorithm to generate a scaled the graph of the desired size, and which preserves the desired graph structure's clustering coefficient.

Once the system identifies the assortativity coefficient and/or the clustering coefficient that satisfies CCN network requirements, the system can generate the necessary CCN topology that satisfies these coefficients using the dK-graph constructing algorithm. The administrator can also use the CCN-deployment system to further refine the CCN topology using real-world performance data obtained after having deployed the CCN topology across a computer network (e.g., the Internet, or any physical network). For example, if the deployed CCN topology experiences congestion conditions, or when down links are detected in a running CCN environment, the system can revise the CCN topology to produce a new graph configuration that preserves the desired dK distribution.

FIG. 2 presents a flow chart illustrating a method 200 for deploying an overlay content centric network across an IP network in accordance with an embodiment. During operation, the system can determine a physical network topology for a computer network of N network nodes (operation 202).

The system then selects a number, k, for a size of an overlay content centric network to deploy over the physical network (operation 204). The system also determines characteristics of the overlay content centric network that can optimize one or more performance metrics. For example, the system can construct and analyze various overlay network topologies to determine an average degree of connectivity that achieves an optimal performance metric for the overlay CCN network (operation 206). The system can also fine-tune the requirements for the overlay network topology by constructing and analyzing various overlay network topologies to determine a degree-of-connectivity distribution that satisfies the average degree of connectivity, and that further optimizes the performance metric for the overlay CCN network (operation 208).

In some embodiments, the system can determine whether to further optimize the performance metrics (operation 210). If the system does not need to further optimize the performance metrics, the system can proceed to generate a network topology of k nodes that satisfies the average degree of connectivity and the degree-of-connectivity distribution (operation 214).

On the other hand, if the system needs to further optimize the performance metrics, the system can determine an optimal degree-distribution matrix that further optimizes the performance metrics for a network topology that satisfies the average degree of connectivity (operation 212). The system then generates a network topology of k nodes that satisfies the average degree of connectivity and the degree-distribution matrix (operation 214).

Once the system has generated an optimized network topology, the system can deploy the overlay CCN network across k nodes of the physical network topology (operation 216).

FIG. 3A illustrates an exemplary degree-of-connectivity distribution 300 in accordance with an embodiment. Specifically, the x-axis for distribution 300 spans a range of average degrees of connectivity, and the y-axis specifies a number of nodes that have a given degree of connectivity.

In some embodiments, the system generates degree-of-connectivity distribution 300 to satisfy a predetermined average degree of connectivity. For example, if the system has determined that an average degree of connectivity of 1.96 can result in near-optimal performance metrics, the system can generate various alternative degree-of-connectivity distributions that satisfy the 1.96 average degree of connectivity. The system can use a power-law distribution function, a Gaussian distribution function, or any other distribution function now known or later developed. While generating distribution 300, the system can fine tune the distribution function's parameters to ensure the distribution satisfies the predetermined average degree of connectivity. The system can test these various distribution functions by generating and simulating various network topologies that satisfy these distributions, and selects a distribution that further improves the quality metrics.

FIG. 3B illustrates an exemplary degree-distribution matrix 350 in accordance with an embodiment. Specifically, the rows and columns of degree-distribution matrix 350 span various degrees of connectivity for two neighboring network nodes. Also, distribution matrix 350 can include a square matrix, and each element of distribution matrix 350 corresponds to a unique degree combination. Each cell (i,j) of distribution matrix 350 shows the probability of a node with degree i connecting to a node of degree j. For example, occurrence value 352 can correspond to a probability that two neighboring nodes in the CCN topology have the given degree of value m and value n, where the node of degree value m has an active interface to the node of degree value n. Alternatively, occurrence value 352 can include a total number of connections (or a fraction of all possible connections) that are between two neighboring nodes in the CCN topology have the given degree of value m and value n.

Also, the system can generate degree-distribution matrix 350 to satisfy a predetermined average degree of connectivity. In some embodiments, the system can generate matrix 350 by first entering values based on a predetermined distribution function, and then adjusting the occurrence values at various cells to further improve the quality metrics while preserving the predetermined average degree of distribution. In some other embodiments, the system can generate matrix 350 by first entering randomly generated occurrence values for each cell across matrix 350. The system then adjusts the occurrence values at various cells to further improve the quality metrics, and to preserve the predetermined average degree of distribution.

FIG. 4 presents a flow chart illustrating a method 400 for determining an average degree of connectivity that optimizes a performance metric in accordance with an embodiment. During operation, the system can analyze various average degrees of connectivity values to select a value with a highest performance metric. For example, the system can select an average degree of connectivity for the k nodes (operation 402), and generates a network topology of k nodes that satisfies the average degree of connectivity (operation 404). The system then computes a performance metric for the network topology (operation 406), and determines whether to analyze another degree of connectivity value (operation 408).

If the system has more average degree of connectivity values to analyze, the system can return to operation 402. Otherwise, the system can proceed to select an average degree of connectivity with a highest performance metric (operation 410).

FIG. 5 presents a flow chart illustrating a method for determining a distribution function and function parameters that optimize a performance metric in accordance with an embodiment. During operation, the system can analyze various distribution functions and function parameters to select a value with a highest performance metric. For example, the system can select a distribution function for the k nodes (operation 502), and selects parameters for the distribution function (operation 504). In some embodiments, the distribution function can include a power-law distribution, a Gaussian distribution, or any other distribution function now known or later developed.

The system then generates a network topology of k network nodes (operation 506), and computes a performance metric for the network topology (operation 508). The system generates the network topology so that it satisfies the average degree of connectivity, and satisfies the distribution function and the parameters. Also, the system can store the performance metric in association with the average degree of connectivity, the distribution function, and the function parameters, such as in a flat file (e.g., a spreadsheet document) or in a database repository.

In some embodiments, the system can generate and test additional alternative network topologies for other function parameters, or for other distribution functions. For example, if the system needs to analyze other parameters for the same distribution function (operation 510), the system can return to operation 504 to select other parameters, and to compute a performance metric for these parameters. Otherwise, if the system needs to analyze a different distribution function (operation 512), the system can return to operation 502 to select another distribution function and function parameters for the k nodes, and to compute a performance metric for this other function and its parameters.

Once the system has computed performance metrics for various distribution functions and various alternative function parameters, the system can determine the highest computed performance metric, and can select a distribution function and function parameters that are stored in association with the highest performance metric (operation 514). The system can use this distribution function and function parameters to produce network topologies with a near-optimal performance metric.

FIG. 6 illustrates an exemplary apparatus 600 that facilitates deploying an overlay content centric network across an IP network in accordance with an embodiment. Apparatus 600 can comprise a plurality of modules which may communicate with one another via a wired or wireless communication channel. Apparatus 600 may be realized using one or more integrated circuits, and may include fewer or more modules than those shown in FIG. 6. Further, apparatus 600 may be integrated in a computer system, or realized as a separate device which is capable of communicating with other computer systems and/or devices. Specifically, apparatus 600 can comprise a topology-characterizing module 602, a topology-generating module 604, a network-analyzing module 606, and a CCN-deploying module 608.

In some embodiments, topology-characterizing module 602 can determine a number, k, of network nodes for a CCN network, and can determine at least an average degree of connectivity and a degree-of-connectivity distribution that achieves an optimal performance metric for the CCN network. Topology-generating module 604 can generate a network topology of k network nodes that satisfies the average degree of connectivity, and satisfies the degree-of-connectivity distribution. Network-analyzing module 606 can select k of network nodes of a computer network on which to overlay the CCN network, such that the selected nodes satisfy the generated network topology for the CCN network. Also, CCN-deploying module 608 can deploy the CCN network across the k nodes of the computer network.

FIG. 7 illustrates an exemplary computer system 702 that facilitates deploying an overlay content centric network across an IP network in accordance with an embodiment. Computer system 702 includes a processor 704, a memory 706, and a storage device 708. Memory 706 can include a volatile memory (e.g., RAM) that serves as a managed memory, and can be used to store one or more memory pools. Furthermore, computer system 702 can be coupled to a display device 710, a keyboard 712, and a pointing device 714. Storage device 708 can store operating system 716, CCN-deployment system 718, and data 728.

CCN-deployment system 718 can include instructions, which when executed by computer system 702, can cause computer system 702 to perform methods and/or processes described in this disclosure. Specifically, CCN-deployment system 718 may include instructions for determining a number, k, of network nodes for a CCN network, and determining at least an average degree of connectivity and a degree-of-connectivity distribution that achieves an optimal performance metric for the CCN network (topology-characterizing module 720). Further, CCN-deployment system 718 can include instructions for generating a network topology of k network nodes that satisfies the average degree of connectivity, and satisfies the degree-of-connectivity distribution (topology-generating module 722).

CCN-deployment system 718 can include instructions for select k of network nodes of a computer network on which to overlay the CCN network, such that the selected nodes satisfy the generated network topology for the CCN network (network-analyzing module 724). CCN-deployment system 718 can also include instructions for deploying the CCN network across the k nodes of the computer network (CCN-deploying module 726).

Data 728 can include any data that is required as input or that is generated as output by the methods and/or processes described in this disclosure. Specifically, data 728 can store at least a network topology of an underlying physical network, a series of network topologies for various graph sizes k and for various average degrees of connectivity d, performance metrics for the various network topologies, and an optimized topology for a CCN network to deploy across the underlying physical network.

The data structures and code described in this detailed description are typically stored on a computer-readable storage medium, which may be any device or medium that can store code and/or data for use by a computer system. The computer-readable storage medium includes, but is not limited to, volatile memory, non-volatile memory, magnetic and optical storage devices such as disk drives, magnetic tape, CDs (compact discs), DVDs (digital versatile discs or digital video discs), or other media capable of storing computer-readable media now known or later developed.

The methods and processes described in the detailed description section can be embodied as code and/or data, which can be stored in a computer-readable storage medium as described above. When a computer system reads and executes the code and/or data stored on the computer-readable storage medium, the computer system performs the methods and processes embodied as data structures and code and stored within the computer-readable storage medium.

Furthermore, the methods and processes described above can be included in hardware modules. For example, the hardware modules can include, but are not limited to, application-specific integrated circuit (ASIC) chips, field-programmable gate arrays (FPGAs), and other programmable-logic devices now known or later developed. When the hardware modules are activated, the hardware modules perform the methods and processes included within the hardware modules.

The foregoing descriptions of embodiments of the present invention have been presented for purposes of illustration and description only. They are not intended to be exhaustive or to limit the present invention to the forms disclosed. Accordingly, many modifications and variations will be apparent to practitioners skilled in the art. Additionally, the above disclosure is not intended to limit the present invention. The scope of the present invention is defined by the appended claims.

Claims (24)

What is claimed is:

1. A computer-implemented method, comprising:

determining, by a computing device, a number k, of network nodes for a content centric networking (CCN) network;

determining an average node degree as twice a number of edges divided by a number of nodes, a degree-of-connectivity distribution, and a joint degree or higher-order distribution, that achieves an optimal performance metric for the CCN network to transmit a CCN Interest, wherein the joint degree distribution indicates an occurrence for a respective pair of node degrees, and wherein the higher-order distribution indicates a probability distribution of loops with at least three nodes;

generating a network topology of k network nodes that satisfies the average node degree, and satisfies the degree-of-connectivity distribution and joint degree or higher-order distribution;

mapping the k nodes of the generated network topology to nodes of a physical computer network; and

transmitting the CCN Interest via the physical computer network according to the mapped network topology.

2. The method of claim 1, wherein mapping the k nodes of the generated network topology to nodes of the physical computer network involves selecting the k network nodes of the physical computer network on which to overlay the CCN network, such that the selected nodes satisfy the generated network topology for the CCN network; and

wherein the method further comprises deploying the CCN network across the k nodes selected from the physical computer network.

3. The method of claim 1, wherein the performance metrics include at least one of:

CCN Interest overhead;

a number or percentage of CCN Interest retransmissions; and

an Interest-to-Content-Object round-trip delay.

4. The method of claim 1, wherein determining the average node degree involves:

iterating over one or more average node degrees, to generate a network topology of k network nodes for each average node degree;

computing a performance metric for each network topology; and

selecting an average node degree with a highest performance metric.

5. The method of claim 1, wherein determining the degree-of-connectivity distribution involves determining an optimal distribution based on one or more of:

generating the degree-distribution matrix to indicate the occurrence value for each pair of node degrees, wherein the degree-distribution matrix is multi-dimensional, and achieves an optimal performance metric for a network topology of the k network nodes that satisfies the average node degree.

10. A non-transitory computer-readable storage medium storing instructions that when executed by a computer cause the computer to perform a method:

determining a number k, of network nodes for a content centric networking (CCN) network;

determining an average node degree as twice a number of edges divided by a number of nodes, a degree-of-connectivity distribution, and a joint degree or higher-order distribution, that achieves an optimal performance metric for the CCN network to transmit a CCN Interest, wherein the joint degree distribution indicates an occurrence for a respective pair of node degrees, and wherein the higher-order distribution indicates a probability distribution of loops with at least three nodes;

generating a network topology of k network nodes that satisfies the average node degree, and satisfies the degree-of-connectivity distribution and joint degree or higher-order distribution;

mapping the k nodes of the generated network topology to nodes of a physical computer network; and

transmitting the CCN Interest via the physical computer network according to the mapped network topology.

11. The non-transitory computer-readable storage medium of claim 10, wherein mapping the k nodes of the generated network topology to nodes of the physical computer network involves selecting the k network nodes of the physical computer network on which to overlay the CCN network, such that the selected nodes satisfy the generated network topology for the CCN network; and

wherein the method further comprises deploying the CCN network across the k nodes selected from the physical computer network.

generating the degree-distribution matrix to indicate the occurrence value for each pair of node degrees, wherein the degree-distribution matrix is multi-dimensional, and achieves an optimal performance metric for a network topology of the k network nodes that satisfies the average node degree.

18. An apparatus, comprising:

a processor; and

storage medium storing instructions that when executed by the processor cause the apparatus to perform a method, the method comprising:

determining a number k, of network nodes for a content centric networking (CCN) network;

determining an average node degree as twice a number of edges divided by a number of nodes, a degree-of-connectivity distribution, and a joint degree or higher-order distribution, that achieves an optimal performance metric for the CCN network to transmit a CCN Interest, wherein the joint degree distribution indicates an occurrence for a respective pair of node degrees, and wherein the higher-order distribution indicates a probability distribution of loops with at least three nodes;

generating a network topology of k network nodes that satisfies the average node degree, and satisfies the degree-of-connectivity distribution and joint degree or higher-order distribution;

mapping the k nodes of the generated network topology to nodes of a physical computer network; and

transmitting the CCN Interest via the physical computer network according to the mapped network topology.

19. The apparatus of claim 18, wherein mapping the k nodes of the generated network topology to nodes of the physical computer network involves selecting k network nodes of the physical computer network on which to overlay the CCN network, such that the selected nodes satisfy the generated network topology for the CCN network; and

wherein the method further comprises deploying the CCN network across the k nodes selected from the physical computer network.

20. The apparatus of claim 18, wherein determining the average node degree involves:

iterating over one or more average node degrees, to generate a network topology of k network nodes for each average node degree;

generating the optimal degree-distribution matrix to indicate the occurrence value for each pair of node degrees, wherein the degree-distribution matrix is multi-dimensional, and achieves an optimal performance metric for a network topology of the k network nodes that satisfies the average node degree.

Generating a hierarchical data structure associated with a plurality of known arbitrary-length bit strings used for detecting whether an arbitrary-length bit string input matches one of a plurality of known arbitrary-length bit string

Generating a hierarchical data structure associated with a plurality of known arbitrary-length bit strings used for detecting whether an arbitrary-length bit string input matches one of a plurality of known arbitrary-length bit string

Schein, Jeffrey, and Steven T. Bushby. A Simulation Study of a Hierarchical, Rule-Based Method for System-Level Fault Detection and Diagnostics in HVAC Systems. US Department of Commerce,[Technology Administration], National Institute of Standards and Technology, 2005.